JP2018034735A - Wheel support rolling bearing unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a structure which can suppress the rotation imbalance of a hub having a rotation-side flange even if through-holes are formed in a plurality of points having unequal intervals with respect to a circumferential direction in the rotation-side flange, and the structure which allows the moment rigidity of the rotation-side flange to approach uniformly over the entire circumference.SOLUTION: Volumes of first ribs 20a, 20a near through-holes 19a, 19a out of ribs 20a, 20b which are formed in a plurality of points in a circumferential direction at an inside face of a rotation-side flange 11a in an axial direction are set larger than volumes of second ribs 20b, 20b which are apart from the through-holes 19a, 19a.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an improvement of a rolling bearing unit for supporting a wheel for rotatably supporting a wheel of an automobile with respect to a suspension device.

  5 and 6 show an example of a conventional structure described in Patent Document 1 as a wheel bearing rolling bearing unit for rotatably supporting a wheel with respect to an automobile suspension device. The wheel-supporting rolling bearing unit 1 includes an outer ring 2 that is a stationary side race ring, a hub 3 that is a rotation side race ring, and a plurality of balls 4 and 4.

  Outer ring 2 has double-row outer ring raceways 5a and 5b on the inner peripheral surface and stationary flange 6 on the outer peripheral surface. Such an outer ring 2 is coupled and fixed to a knuckle that constitutes a suspension device by bolts screwed into screw holes 7 formed at a plurality of positions in the circumferential direction of the stationary flange 6, so that it does not rotate during use. .

  The hub 3 is formed by coupling and fixing a hub main body 8 and an inner ring 9. The hub 3 has double-row inner ring raceways 10 a and 10 b and a rotation side flange 11 on the outer peripheral surface. It rotates together with a wheel and a brake rotating member coupled and fixed to each other.

The hub body 8 has an outer peripheral surface near the outer flange in the axial direction and the outer ring inner ring raceway 10a in the outer row of the double row inner ring raceways 10a and 10b in the axial middle portion. Small-diameter step portions 12 are directly formed at portions near the inner end in the axial direction.
In the present specification and claims, “outside” in the axial direction means the left side in FIGS. 1 and 5 that is the outer side in the width direction of the vehicle when assembled to the vehicle body. The right side of FIGS. 1 and 5, which is the center side in the width direction of the vehicle in the assembled state, is referred to as “inside” in the axial direction.

  The inner ring 9 is formed directly on the outer peripheral surface with the inner ring raceway 10b in the inner row of the double row inner ring raceways 10a and 10b. Such an inner ring 9 is clamped by a caulking portion 13 formed on the inner end portion in the axial direction of the hub main body 8 in a state where the inner ring 9 is fitted and fixed to the small diameter step portion 12 of the hub main body 8. As a result, the hub body 8 is fixedly coupled.

  A plurality of balls 4, 4 are provided for each row in a state where they are held by cages 14, 14 between the double row outer ring raceways 5a, 5b and the double row inner ring raceways 10a, 10b. Each is provided so that it can roll freely.

  In the case of the conventional structure, ribs 20 and 20 that extend radially at a plurality of locations (five locations in the illustrated example) that are equally spaced in the circumferential direction on the inner side surface in the axial direction of the rotation-side flange 11. Is provided. In such a rotation-side flange 11, portions corresponding to the ribs 20, 20 in the circumferential direction are the thick portions 15, 15, and portions not corresponding to the ribs 20, 20 are the thin portions 16, 16. That is, the rotation side flange 11 has the thick portions 15 and the thin portions 16 alternately in the circumferential direction.

  In addition, it penetrates in the axial direction at a plurality of locations at equal intervals in the circumferential direction of the rotation-side flange 11 and at portions aligned with the ribs 20 and 20 (thick portions 15 and 15) in the circumferential direction. In this state, the mounting holes 17 are formed. Then, the base end portions of a plurality of studs 18 having serration portions in part thereof are press-fitted into these mounting holes 17, 17, and the wheel, disc rotor, and drum brake constituting the wheel are inserted into the rotation side flange 11. The rotating member for braking such as can be supported and fixed.

  In addition, a plurality of portions of the rotation side flange 11 that are equally spaced in the circumferential direction, and portions that are separated from the ribs 20 and 20 (thick portions 15 and 15) in the circumferential direction (the thin portions 16). , 16 are provided with through-holes 19 and 19 so as to penetrate in the axial direction. These through-holes 19 and 19 are provided, for example, for the purpose of reducing the weight of the rotation-side flange 11 or performing the work of connecting the outer ring 2 and brake parts to a mating member such as the knuckle. ing.

In general, each of the through holes 19, 19 suppresses the rotational imbalance of the hub 3 having the rotation-side flange 11, and in order to make the moment rigidity of the rotation-side flange 11 close uniformly over the entire circumference, It is provided at equal intervals in the direction.
However, for example, a tool is inserted into each of the through holes 19, 19, and in order to efficiently perform operations such as the coupling of the outer ring 2 and the brake parts to the mating member with these tools, it is a target. Depending on the working environment, it may be convenient for the through holes 19, 19 to be provided at unequal intervals in the circumferential direction.

However, when the through holes 19 are provided at unequal intervals in the circumferential direction, the rotation unbalance of the hub 3 having the rotation side flange 11 increases accordingly, and the rotation side flange 11 There arises a problem that the moment stiffness becomes non-uniform over the entire circumference.
As a countermeasure for such a problem, for example, it is conceivable to attach a weight to a part of the rotation side flange in the circumferential direction.
However, even if such countermeasures can suppress the rotation imbalance of the hub having the rotation side flange, the moment rigidity of the rotation side flange cannot be made uniform over the entire circumference.

JP 2008-55984 A

  In view of the circumstances as described above, the present invention provides a plurality of through holes at a plurality of locations at unequal intervals in the circumferential direction of the rotation-side flange and at portions that are separated from the plurality of ribs in the circumferential direction. Even in this case, it was invented to realize a structure capable of suppressing the rotation imbalance of the rotation side bearing ring having the rotation side flange and making the moment rigidity of the rotation side flange uniform over the entire circumference. Is.

The wheel bearing rolling bearing unit of the present invention includes a stationary side race ring, a rotation side race ring, and a plurality of rolling elements.
Among these, the stationary-side raceway has one or more stationary-side raceways on its peripheral surface, and is not supported and rotated by the suspension device during use.
The rotation-side raceway has one or a plurality of rotation-side raceways on its peripheral surface, and has an outward flange shape for fixing a wheel and a braking rotary member (for example, a disc rotor or a drum brake), and a substantially annular shape. It has a rotating flange and rotates with this wheel when in use.
Each of the rolling elements is provided between the stationary track and the rotating track so as to freely roll. As such rolling elements, balls, tapered rollers, cylindrical rollers, or the like can be used.
Also, radially extending ribs are provided on the inner side surface in the axial direction of the rotation-side flange at a plurality of locations that are equally spaced in the circumferential direction.
In addition, the rotation side flange is provided with attachment holes for attaching coupling members (for example, studs, hub bolts, etc.) used to fix the wheel to the rotation side flange at portions aligned with the ribs. In addition, a plurality of through holes are provided at a plurality of locations that are unequally spaced in the circumferential direction and at portions that are separated from the ribs in the circumferential direction.
Further, the volume (weight) of the first rib that is a rib close to the through hole in the circumferential direction is larger than the volume (weight) of the second rib that is a rib far from the through hole in the circumferential direction. . Thereby, the moment rigidity of the first rib is larger than the moment rigidity of the second rib.

In carrying out the present invention, for example, a configuration in which the length dimension of the first rib in the radial direction (radial direction) is larger than the length dimension of the second rib in the radial direction is employed. Can do.
Moreover, when implementing this invention, the structure which the width dimension regarding the circumferential direction of the said 1st rib is larger than the width dimension regarding the circumferential direction of the said 2nd rib can be employ | adopted, for example. .
Moreover, when implementing this invention, the structure whose thickness dimension regarding the axial direction of the said 1st rib is larger than the thickness dimension regarding the axial direction of the said 2nd rib can be employ | adopted, for example. .

  In the case of the rolling bearing unit for supporting a wheel according to the present invention, through holes are provided at a plurality of locations at unequal intervals with respect to the circumferential direction of the rotation side flange, and at portions separated from the plurality of ribs with respect to the circumferential direction. Since the volume of the first rib, which is a rib close to the through hole in the circumferential direction, is larger than the volume of the second rib, which is a rib far from the through hole in the circumferential direction, although the structure is provided, The rotation imbalance of the rotation side bearing ring having the rotation side flange can be suppressed, and the moment rigidity of the rotation side flange can be made uniform over the entire circumference.

Sectional drawing of the rolling bearing unit for wheel support which shows the 1st example of embodiment of this invention. The figure which took out the hub main body similarly and was seen from the axial direction inner side. The figure similar to FIG. 2 which shows the 2nd example of embodiment of this invention. The figure similar to FIG. 2 which shows the 3rd example of embodiment of this invention. Sectional drawing which shows an example of the rolling bearing unit for wheel support of the conventional structure. The figure which took out the hub main body similarly and was seen from the axial direction inner side.

[First example of embodiment]
A first example of the embodiment of the present invention will be described with reference to FIGS.
The wheel-supporting rolling bearing unit 1a of the present example is configured to rotatably support a wheel 22 and a braking rotary member (disc rotor) 23 that constitute wheels as drive wheels with respect to a knuckle 21 that constitutes a suspension device. Therefore, on the inner diameter side of the outer ring 2a corresponding to the stationary side ring described in the claims, a hub 3a corresponding to the rotation side ring and a plurality of balls 4a and 4a corresponding to rolling elements are provided. Via the support.

  The outer ring 2a is made of, for example, medium carbon steel and has a substantially cylindrical shape as a whole. The outer ring 2a has double-row outer ring raceways 5c and 5d on the inner peripheral surface and a stationary flange 6a on the outer peripheral surface. Yes. Such an outer ring 2a is fixed to the knuckle 21 by a plurality of bolts 24 screwed into screw holes 7a formed at a plurality of locations in the circumferential direction of the stationary flange 6a.

  The hub 3a is formed by coupling and fixing a hub body 8a and an inner ring 9a, and has double-row inner ring raceways 10c and 10d and a rotation side flange 11a on the outer peripheral surface. In use, the hub 3a rotates together with the wheel 22 and the brake rotating member 23 fixedly coupled to the rotation side flange 11a.

  The hub body 8a is manufactured by forging a material such as medium carbon steel. Further, of the outer peripheral surface of the hub main body 8a, the rotation side flange 11a having an outward flange shape is provided at a portion near the outer end in the axial direction, and the outer row of the inner ring raceways 10c and 10d in the double row is provided at an intermediate portion in the axial direction. The inner ring raceway 10c is directly formed with a small-diameter step portion 12a at a portion near the inner end in the axial direction.

  The inner ring 9a is made of, for example, bearing steel and has a cylindrical shape as a whole, and an inner row of inner ring raceways 10d out of the double row of inner ring raceways 10c and 10d is formed on the outer peripheral surface thereof. Such an inner ring 9a is fitted and fixed to the small-diameter step portion 12a of the hub body 8a, and its inner end surface in the axial direction is suppressed by a caulking portion 13a formed at the inner end portion in the axial direction of the hub body 8a. Thus, it is fixedly coupled to the hub body 8a.

  The balls 4a and 4a are made of bearing steel or ceramic, for example, and are held by the cages 14a and 14a between the double-row outer ring raceways 5c and 5d and the double-row inner ring raceways 10c and 10d. In a state, a plurality of pieces are provided so as to roll freely for each row. In this state, each of the balls 4a and 4a arranged in a double row is provided with a contact angle of a rear combination type together with a preload. Thus, the hub 3a is supported on the inner diameter side of the outer ring 2a so as not to rattle and rotatably while supporting a radial load and an axial load. Further, both axial end openings of the cylindrical space in which the balls 4a and 4a are installed are sealed by seal rings 25a and 25b, respectively.

  Furthermore, since the wheel bearing rolling bearing unit 1a of this example is for driving wheels (front wheels of FF vehicles, rear wheels of FR vehicles and RR vehicles, all wheels of 4WD vehicles), the hub 3a (hub body 8a) A spline hole 26 is formed in the center portion of each. A spline shaft 28 fixed to the outer end surface of the constant velocity joint outer ring 27 is inserted into the spline hole 26. At the same time, a nut 29 is screwed onto the tip of the spline shaft 28 and further tightened, whereby the hub body 8a is sandwiched between the nut 29 and the constant velocity joint outer ring 27.

  The outer peripheral surface of the rotation side flange 11a has a cylindrical shape centered on the central axis of the hub body 8a. The axially outer surface of the rotation side flange 11a is a flat surface orthogonal to the central axis of the hub body 8a. On the other hand, the inner side surface in the axial direction of the rotation side flange 11a is an uneven surface in the circumferential direction. That is, the radially extending first ribs 20a and second ribs 20b are alternately arranged in the circumferential direction at a plurality of positions at equal intervals in the circumferential direction on the inner surface in the axial direction of the rotation side flange 11a ( In the illustrated example, they are arranged at four locations of 2 + 2. Each of the ribs 20a and 20b is integrally provided in a range extending from a radially inner end portion to a radially outer end portion of the rotation side flange 11a. In such a rotation-side flange 11a, the portions corresponding to the first rib 20a and the second rib 20b in the circumferential direction are thick portions 15a and 15b, and the portions not corresponding to the thin ribs 16a and 16a are the same. It has become. That is, the said rotation side flange 11a has the thick part 15a (15b) and the thin part 16a alternately with respect to the circumferential direction. Further, a pair of thin portions 16a disposed on both sides in the circumferential direction of the thick portions 15a and 15b on the radially outer side of the thick portions 15a and 15b of the rotation side flange 11a, Outer-diameter side thin portions 30 and 30 are provided to make 16a continuous.

Further, the thickness dimension (bulge dimension from the thin portion 16a) T in the axial direction of the first rib 20a and the second rib 20b is the same. Therefore, the thickness dimension in the axial direction of each of the thick portions 15a and 15b is also the same. Furthermore, the thickness dimensions in the axial direction of the thin portions 16a, 16a and the outer diameter side thin portions 30, 30 are also the same. However, in the case of this example, the lengths (L _a , L _b ) in the radial direction of the first rib 20a and the second rib 20b are different from each other between the first rib 20a, 20a and the second rib 20b, 20b. (L _a > L _b ). This point will be specifically described later.

  In addition, the first rib 20a and the second rib 20b (thick portion 15a, the thick portion 15a, the plurality of locations (four locations in the illustrated example) that are equally spaced in the circumferential direction of the rotation-side flange 11a and the circumferential direction. 15b), the mounting holes 17a and 17a are provided in the axially penetrating state, particularly in the circumferential center of the first rib 20a and the second rib 20b. . These mounting holes 17a and 17a are circular holes (or female screw holes) of the same size, and are located on the same pitch circle and close to the radially outer ends of the first rib 20a and the second rib 20b. It is provided in the part. And the base end part of the several stud 18a which has a serration part in the one part in such attachment holes 17a and 17a is press-fitted. And after inserting the front-end | tip part of each said stat 18a in the through-hole respectively formed in the said wheel 22 and the said brake rotation member 23, the nut 31 is screwed together, The shaft of the said rotation side flange 11a is carried out. The braking rotating member 23 and the wheel 22 are fixed to the outer surface in the direction.

Further, the rotation side flange 11a is disengaged from the first rib 20a and the second rib 20b (thick portions 15a and 15b) at a plurality of positions in the circumferential direction (four positions in the illustrated example) and in the circumferential direction. Through-holes 19a and 19a are provided in the state (parts aligned with the thin-walled portions 16a and 16a) in a state of penetrating in the axial direction. In the case of this example, each of these through holes 19a, 19a is a circular hole of the same size, and is provided on the same pitch circle. These through-holes 19a and 19a are, for example, for the purpose of reducing the weight of the rotating flange 11a, and for the purpose of connecting the outer ring 2a and a brake component (not shown) to a mating member such as the knuckle 21. Is provided.
When the present invention is implemented, the shape of the plurality of through holes (19a) provided in the rotation side flange as viewed from the axial direction is not limited to the circular shape as shown in FIG. Or other polygons). Further, the sizes of the plurality of through holes (19a) can be made different from each other.

  Further, in the case of this example, a tool is inserted into each of the through holes 19a, 19a so that the work such as the coupling of the outer ring 2a and the brake parts to the mating member can be performed efficiently with these tools. For this purpose, the through holes 19a and 19a are provided at unequal intervals in the circumferential direction according to the target working environment. Specifically, each of the through holes 19a and 19a is close to the first rib 20a and far from the second rib 20b among the two ribs 20a and 20b positioned on both sides in the circumferential direction. The position.

  Accordingly, in the case of this example, the volume (weight, moment stiffness) of the first rib 20a is made larger than the volume (weight, moment stiffness) of the second rib 20b.

To this end, specifically, the first rib 20a, the length L _a in the radial direction of 20a, the second ribs 20b, are larger than the length L _b in the radial direction of 20b ( L _a > L _b ). In other words, the radially outer ends of the first ribs 20a and 20a are compared with the radially outer ends of the second ribs 20b and 20b in comparison with the chain line α (the second rib 20b) in FIG. The portion extending radially outward from the corresponding portion) extends outward in the radial direction.

  In the case of this example, by adopting a configuration in which the volume of the first ribs 20a, 20a is larger than the volume of the second ribs 20b, 20b as described above, the periphery of the through holes 19a, 19a The weight of the part is supplemented by the weight of the first ribs 20a, 20a, and the moment rigidity of the peripheral part of the through holes 19a, 19a is supplemented by the moment rigidity of the first ribs 20a, 20a, thereby the rotation. The rotation imbalance of the hub 3a having the side flange 11a is suppressed, and the moment rigidity of the rotation side flange 11a is made uniform over the entire circumference.

  As described above, according to the rolling bearing unit for supporting a wheel of this example, the ribs 20a and 20b are arranged at a plurality of positions at unequal intervals in the circumferential direction of the rotation side flange 11a and from the ribs 20a and 20b in the circumferential direction. Although it has a structure in which through holes 19a and 19a are respectively provided in the detached portion, it is possible to suppress the rotation imbalance of the hub 3a having the rotation side flange 11a and to reduce the moment rigidity of the rotation side flange 11a over the entire circumference. It is possible to get closer to uniform.

[Second Example of Embodiment]
A second example of the embodiment of the present invention will be described with reference to FIG.
Also in the case of this example, among the plurality of first ribs 20a and second ribs 20c (thick portions 15a and 15c) provided on the rotation-side flange 11b, the through holes 19a and 19a respectively located on both sides in the circumferential direction. The volume of the near first rib 20a is larger than the volume of the second rib 20c far from the through holes 19a and 19a located on both sides in the circumferential direction.

For this reason, in the case of this example, unlike the first example of the above-described embodiment, the first rib 20a, the width W _a in the circumferential direction of 20a, the second rib 20c, It is larger than the width dimension W _{c in} the circumferential direction of 20 _c (W _a > W _c ). In other words, the circumferential ends of the first ribs 20a, 20a are compared with the circumferential ends of the second ribs 20c, 20c, as shown by chain lines β, β (second ribs) in FIG. It extends to both sides in the circumferential direction by the amount located on both sides in the circumferential direction than the portion corresponding to 20c.

And also in the case of this example, by adopting a configuration in which the volume of the first ribs 20a, 20a is larger than the volume of the second ribs 20c, 20c as described above, the peripheral portions of the through holes 19a, 19a are adopted. Is supplemented by the weight of the first ribs 20a and 20a, and the moment rigidity of the peripheral portions of the through holes 19a and 19a is supplemented by the moment rigidity of the first ribs 20a and 20a, thereby The rotation unbalance of the hub 3a having the flange 11b is suppressed, and the moment rigidity of the rotation side flange 11b is made uniform over the entire circumference.
Other configurations and operations are the same as those in the first example of the embodiment described above.

[Third example of embodiment]
A third example of the embodiment of the present invention will be described with reference to FIG.
In the case of this example, the first rib 20d and the second rib 20e provided at a plurality of locations in the circumferential direction on the inner surface in the axial direction of the rotation side flange 11c (thick portions 15d provided at a plurality of locations in the circumferential direction of the rotation side flange 11c). , 15e) and the number of mounting holes 17a, 17a provided at a plurality of locations that are equally spaced in the circumferential direction of the rotation-side flange 11c and that are aligned with the ribs 20d, 20e in the circumferential direction. Each of the numbers is five more than in the first example of the embodiment described above.

  In the case of this example, the number of the through holes 19a, 19a provided at unequal intervals in the circumferential direction with respect to the thin portions 16a, 16a constituting the rotation side flange 11c is the first example of the above-described embodiment. As in the case of, there are four. These four through-holes 19a and 19a are in contrast to the four first ribs 20d and 20d located in the portion of the five first ribs 20d and the second ribs 20e that are off the upper end in FIG. Each one is arranged at a position close to the circumferential direction. On the other hand, each of the through holes 19a, 19a is disposed far from the one second rib 20e located at the upper end in FIG. 4 in the circumferential direction.

  Also in this example, the volume of the first rib 20d is made larger than the volume of the second rib 20e.

For this reason, in the case of this example, unlike the case of the first example of the above-described embodiment, the width dimension W _d in the circumferential direction of the first ribs 20d, 20d is set to the width of the second rib 20e. It is larger than the width dimension W _{e in the} circumferential direction (W _d > W _e ). In other words, the end of one side or the other side of the first ribs 20d, 20d (the through hole 19a side close to itself) is connected to one side or the other side of the second rib 20e. Compared to the end portion, it extends to one side or the other side in the circumferential direction by the amount located on one side or the other side in the circumferential direction from the chain line γ (the portion corresponding to the second rib 20e) in FIG.

Also in this example, the weight of the peripheral portions of the through holes 19a and 19a is adopted by adopting the configuration in which the volume of the first ribs 20d and 20d is larger than the volume of the second rib 20e as described above. Is supplemented by the weight of the first ribs 20d, 20d, and the moment rigidity of the peripheral portions of the through holes 19a, 19a is supplemented by the moment rigidity of the first ribs 20d, 20d. Compared to the case where the volumes of 20e are the same, the rotation imbalance of the hub 3a having the rotation side flange 11c is suppressed, and the moment rigidity of the rotation side flange 11c is made uniform over the entire circumference. ing.
Other configurations and operations are the same as those of the first example of the embodiment described above.

In addition, this invention can also be implemented combining the structure of each embodiment mentioned above suitably.
Further, in the present invention, in order to make the volumes of the plurality of ribs (thick portions) different from each other, the thickness dimension T (see FIG. 1) of each rib in the axial direction can be made different from each other. That is, the closer to the holes ribs, the head of the stud 18a has a thickness dimension T _A in the axial direction other than the abutting portion larger than the thickness T _B in the axial direction of the distant ribs from hole (T _A > T _B ), the volume of the ribs close to the through holes can be made larger than the volume of the ribs far from the through holes, while making the sizes of all the studs 18a common.

  The present invention can be applied not only to the inner ring rotation type wheel support rolling bearing unit as shown in each example of the embodiment but also to the outer ring rotation type wheel support rolling bearing unit. Similarly, the present invention can be applied not only to a wheel support rolling bearing unit for driving wheels but also to a wheel support rolling bearing unit for driven wheels as shown in FIG.

DESCRIPTION OF SYMBOLS 1, 1a Rolling bearing unit for wheel support 2, 2a Outer ring 3, 3a Hub 4, 4a Ball 5a, 5b, 5c, 5d Outer ring raceway 6, 6a Stationary side flange 7, 7a Screw hole 8, 8a Hub body 9, 9a Inner ring 10a to 10d Inner ring raceway 11, 11a to 11c Rotating flange 12, 12a Small diameter step portion 13, 13a Caulking portion 14, 14a Cage 15, 15a to 15e Thick portion 16, 16a Thin portion 17, 17a Mounting hole 18, 18a Stud 19, 19a Through hole 20a-20e Rib 21 Knuckle 22 Wheel 23 Braking rotating member 24 Bolt 25a, 25b Seal ring 26 Spline hole 27 Outer ring for constant velocity joint 28 Spline shaft 29 Nut 30 Outer diameter side thin portion 31 Nut

Claims (4)

A stationary side raceway that has a stationary side track on its peripheral surface and is not supported and rotated by a suspension device during use;
A rotation-side raceway having a rotation-side track on the peripheral surface, a rotation-side flange having an outward flange shape for fixing the wheel, and rotating at the time of use;
A plurality of rolling elements provided between the stationary track and the rotating track so as to be freely rollable;
With
On the inner side surface in the axial direction of the rotation side flange, radially extending ribs are provided at a plurality of positions that are equally spaced in the circumferential direction, respectively.
The rotation side flange is provided with an attachment hole for attaching a coupling member used for fixing the wheel to the rotation side flange in a portion aligned with each rib, and is unequal with respect to the circumferential direction. Through holes are provided at portions that are spaced apart from each of the ribs with respect to the circumferential direction at multiple locations,
A wheel bearing rolling bearing unit in which a volume of a first rib that is a rib close to the through hole in the circumferential direction is larger than a volume of a second rib that is a rib far from the through hole in the circumferential direction. The wheel bearing rolling bearing unit according to claim 1, wherein a length dimension of the first rib in the radial direction is larger than a length dimension of the second rib in the radial direction. The wheel support rolling bearing according to claim 1, wherein a width dimension of the first rib in the circumferential direction is larger than a width dimension of the second rib in the circumferential direction. unit. The wheel support rolling bearing according to any one of claims 1 to 3, wherein a thickness dimension of the first rib in the axial direction is larger than a thickness dimension of the second rib in the axial direction. unit.

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